Disclosed herein is a semiconductor integrated circuit device which includes a standard cell with a plurality of fins extending in a first direction and arranged in a second direction that is perpendicular to the first direction. An active fin of the fins forms part of an active transistor. A dummy fin of the fins is disposed between the active fin and an end of the standard cell.
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1. A semiconductor integrated circuit device comprising:
a first cell row comprised of standard cells arranged in a first direction; and
a second cell row comprised of standard cells arranged in the first direction, and disposed adjacent to the first cell row in a second direction that is perpendicular to the first direction, wherein
the first cell row comprises:
a first standard cell having fins extending in the first direction and including an active transistor with a fin structure, the active transistor having at least one of the fins and a gate line extending in the second direction; and
a second standard cell which is a tap cell having a function of fixing a substrate potential, the second standard cell being adjacent to the first standard cell in the first direction, and including fins extending in the first direction, and
the first standard cell has a first fin disposed closest to a cell row boundary between the first and second cell rows, and the second standard cell has a dummy fin disposed at the same position in the second direction as the first fin and a diffusion region supplied with power and disposed at a position farther from the cell row boundary than the dummy fin in the second direction.
2. The semiconductor integrated circuit device of
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This is a continuation of International Application No. PCT/JP2014/002236 filed on Apr. 21, 2014, which claims priority to Japanese Patent Application No. 2013-177182 filed on Aug. 28, 2013. The entire disclosures of these applications are hereby incorporated by reference.
The present disclosure relates to a semiconductor integrated circuit device including a standard cell with transistor having a fin structure.
A standard cell design has been known as a method of forming a semiconductor integrated circuit on a semiconductor substrate. The standard cell design refers to a method of designing a large-scale integrated circuit (LSI) chip by providing in advance, as standard cells, unit logic elements having particular logic functions (for example, an inverter, a latch, a flip-flop, and a full adder), laying out those standard cells on a semiconductor substrate, and connecting those standard cells together through a routing process.
Recently, it has been proposed to utilize transistors with a fin structure (hereinafter referred to as “fin transistors”) in the field of semiconductor devices.
U.S. Pat. No. 8,258,577 shows an exemplary standard cell including fin transistors (
A fin transistor has its characteristics affected by a distance from itself to an adjacent one more strongly than an MOS transistor with a two-dimensional structure does. For example, the current characteristic of such a fin transistor varies according to the oxide definition (OD)-spacing-effect (OSE) caused depending on the distance from its own fin to another transistor's or with a change in physical stress. Also, the fin is raised from the surface of a substrate, and therefore, the capacitance characteristic of such a transistor also varies according to the distance from its own fin to another transistor's. That is to say, the fin transistor has current and capacitance characteristics varying according to the distance from itself to an adjacent one.
In the standard cell design, a standard cell may adjoin standard cells with various configurations. Accordingly, for example, as for a fin transistor disposed near an end of the cell, the distance from its own fin to an adjacent fin varies significantly depending on the design of the adjacent standard cell. Also, for example, in a standard cell arranged on the outer periphery of a circuit block, a fin may be disposed at an infinite distance from an adjacent fin. As can be seen, if the characteristic of such a fin transistor varies significantly according to the cell arrangement, its current and/or capacitance characteristic(s) need to be allowed a certain margin in advance with such a variation taken into account. This, however, may cause a decrease in the performance of the semiconductor integrated circuit or an increase in cost, which is not beneficial.
In view of the foregoing background, it is therefore an object of the present disclosure to reduce, in a semiconductor integrated circuit device including a standard cell with a fin transistor, such an influence of a cell arrangement on the characteristics of the fin transistor and eventually improve the performance of the semiconductor integrated circuit device.
A first aspect of the present disclosure provides a semiconductor integrated circuit device including a first standard cell having a fin transistor. The first standard has a plurality of fins extending in a first direction and arranged in a second direction that is perpendicular to the first direction. The plurality of fins includes: an active fin forming part of an active transistor; and a dummy fin disposed between the active fin and an end of the first standard cell in the second direction.
According to this aspect of the present disclosure, the distance between the active fin and the fin located closer to the end of the cell than the active fin is, i.e., the dummy fin, is determined uniquely regardless of the configuration of another standard cell arranged adjacent to the first standard cell. Thus, the active transistor formed by the active fin has a constant current characteristic regardless of the cell arrangement. This allows for reducing a design margin, and eventually improving the performance of the semiconductor integrated circuit device.
A second aspect of the present disclosure provides a semiconductor integrated circuit device including first and second standard cells each having fin transistors. Each of the first and second standard cells has a plurality of fins extending in a first direction and arranged in a second direction that is perpendicular to the first direction. The first and second standard cells are arranged adjacent to each other, and a dummy fin is disposed on a cell boundary between the first and second standard cells.
According to this aspect of the present disclosure, in the first and second standard cells, the distance between an active fin located near the cell boundary and a dummy fin disposed on the cell boundary is determined uniquely regardless of the configuration of an adjacent standard cell. Thus, the active transistor arranged near the cell boundary has a constant current characteristic regardless of the cell arrangement. This allows for reducing a design margin, and eventually improving the performance of the semiconductor integrated circuit device. Furthermore, the first and second standard cells share the dummy fin. This allows for reducing the cell area while achieving the above advantage. Consequently, the overall circuit area and manufacturing cost of the semiconductor integrated circuit device may be cut down.
A third aspect of the present disclosure provides a semiconductor integrated circuit device comprising: a first cell row comprised of standard cells arranged in a first direction; and a second cell row comprised of standard cells arranged in the first direction, and disposed adjacent to the first cell row in a second direction that is perpendicular to the first direction. The first cell row comprises: a first standard cell including an active transistor with a fin structure and having fins extending in the first direction; and a second standard cell including fins extending in the first direction, and the first standard cell has a first fin disposed closest to a cell row boundary between the first and second cell rows, and the second standard cell has a dummy fin disposed at the same position in the second direction as the first fin.
According to this aspect of the present disclosure, the fin located closest to the cell row boundary in the first standard cell and the dummy fin in the second standard cell are disposed at the same position in the second direction. Thus, the distance between the active fin of the second cell row, located near the cell row boundary, and the fin of the first cell row, located opposite the active fin across the cell row boundary, is determined uniquely regardless of the configuration of the standard cell in the first cell row. Thus, the active transistor located near the cell row boundary has a constant current characteristic regardless of the cell arrangement. This allows for reducing a design margin, and eventually improving the performance of the semiconductor integrated circuit device.
The present disclosure allows for reducing, in a semiconductor integrated circuit device including a standard cell with a fin transistor, an influence of a cell arrangement on the characteristics of the fin transistor. This thus allows for improving the performance of the semiconductor integrated circuit device.
Embodiments of the present disclosure will now be described in detail with reference to the accompanying drawings. In the following description of embodiments, it is assumed that a semiconductor integrated circuit device includes a plurality of standard cells, at least some of which includes a fin transistor.
Also, in this specification, a transistor which contributes to a logical function of the standard cells will be hereinafter referred to as an “active transistor,” and a transistor other than such an active transistor, i.e., a transistor which does not contribute to any logical functions of the standard cells will be hereinafter referred to as a “non-active transistor.” A fin which forms part of the “active transistor” will be hereinafter referred to as an “active fin,” and a fin other than such a fin will be hereinafter referred to as a “dummy fin.” In other words, the “dummy fin” refers herein to either a fin which forms part of a “non-active transistor” or a fin which does not form part of any transistor.
The standard cell 1 illustrated in
The fins 11 and 12 are active fins, and form part of active transistors T1 and T2 which contribute to the logical function of the standard cell 1. That is to say, the fins 11 and 12 are provided with a gate line 15, and a local interconnect 5a to which an input A is supplied is connected to the gate line 15. One end of the fin 11 is connected to a metallic interconnect 7a which outputs an output Y through a local interconnect 5b and a contact 6a. One end of the fin 12 is also connected to the metallic interconnect 7a through a local interconnect 5c and a contact 6b. The other end of the fin 11 is connected to a metallic interconnect 7b through a local interconnect 5d and a contact 6c, The metallic interconnect 7b is also connected to a power supply line 8a. The other end of the fin 12 is connected to a metallic interconnect 7c through a local interconnect 5c and a contact 6d. The metallic interconnect 7c is also connected to a power supply line 8b. The local interconnect refers to an interconnect provided in an interconnect layer which is in direct contact with the fin layer.
On the other hand, the fins 13 and 14 are dummy fins, which form part of non-active transistors that do not contribute to the logical function of the standard cell 1. The active fin 11 and the dummy fin 13 are arranged in a region of the same conductivity type (e.g., in a p-type region), and the active fin 12 and the dummy fin 14 are arranged in another region of the same conductivity type (e.g., in an n-type region). A gate line 16 is provided on the fin 13, and agate line 17 is provided on the fin 14. The gate lines 16 and 17, as well as a gate line 15 provided on the active fins 11 and 12, are arranged in a straight line extending in the vertical direction on the paper. However, the gate lines 16 and 17 are isolated from the gate line 15 via a cut-off region Cut1. In the manufacturing process, a gate line may be formed in a straight line in the vertical direction on the paper so as to extend the active fins 11 and 12 and the dummy fins 13 and 14, and then, may be cut in the cut-off region Cut1. Alternatively, the gate lines 15, 16, and 17 may be provided separately from each other.
The dummy fin 11 is disposed between the active fin 11 and the upper end of the standard cell 1 on the paper. No other fins are disposed between the dummy fin 13 and the upper end of the standard cell 1 on the paper. The dummy fin 13 is disposed closer to the upper end of the standard cell 1 on the paper than any other fin thereof. Likewise, the dummy fin 14 is disposed between the active fin 12 and the lower end of the standard cell 1 on the paper. No other fins are disposed between the dummy fin 14 and the lower end of the standard cell 1 on the paper. The dummy fin 14 is disposed closer to the lower end of the standard cell 1 on the paper than any other fin thereof.
According to the layout design of
On the other hand, in the standard cell 1B of
In the layout designs of
The standard cells 2A and 2B illustrated in
In
According to the layout design of
Furthermore, the standard cells 2A and 2B share the dummy fin 25. This allows for reducing the cell area while achieving the above advantage. Consequently, the overall area and manufacturing cost of the semiconductor integrated circuit device may be cut down.
Optionally, the dummy fin provided on the cell boundary may be connected to an overlying metallic interconnect in order to supply a potential.
The standard cell 2C illustrated in
Now, take a look at the first cell row CR1, for example. The standard cell 3A includes an active transistor with a fin structure, and a fin 31 is an active fin arranged closest to the cell row boundary CRB in the standard cell 3A. In the standard cells 3B, 3C, and 3D arranged continuously with the standard cell 3A, fins 32, 33a, 33b, and 34 are arranged at the same position in the vertical direction on the paper as the active fin 31. For example, the standard cell 3B includes no active transistors with a fin structure, and the fin 32 is a dummy fin. In the standard cell 3C, the fin 33a is an active fin but the fin 33b is a dummy fin.
As can be seen, in the first cell row CR1, the fins including dummy fins are arranged in the respective cells along the cell row boundary CRB. Likewise, in the second cell row CR2, the fins including dummy fins are arranged in the respective cells along the cell row boundary CRB. Such a layout design determines uniquely the distance between an active fin located near the cell row boundary CRB and a fin located opposite the active fin across the cell row boundary CRB, regardless of the layout designs of the cell rows. Thus, the active transistors near the cell boundary CB may have constant current and capacitance characteristics regardless of the cell arrangement. This allows for reducing a design margin, and eventually improving the performance of the semiconductor integrated circuit device.
It is recommended that the active fin 31 and the fins 32, 33a, 33b, and 34 aligned with the active fin 31 be arranged closer to the cell row boundary CRB than the other fins in the first cell row CR1.
The cell designs illustrated in
Note that elements of two or more of the embodiments described above may be used in any arbitrary combination without departing from the spirit of the present disclosure.
The present disclosure is capable of reducing, in a semiconductor integrated circuit device including a standard cell with a fin transistor, an influence of a cell arrangement on the characteristics of the fin transistor. Thus, the present disclosure is useful for improving the performance of the semiconductor integrated circuit device.
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